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I n t e r n a t i o n a l T e l e c o m m u n i c a t i o n U n i o n
ITU-T G.984.1TELECOMMUNICATIONSTANDARDIZATION SECTOROF ITU
(03/2008)
SERIES G: TRANSMISSION SYSTEMS AND MEDIA,DIGITAL SYSTEMS AND NETWORKS
Digital sections and digital line system Optical linesystems for local and access networks
Gigabit-capable passive optical networks(GPON): General characteristics
Recommendation ITU-T G.984.1
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ITU-T G-SERIES RECOMMENDATIONS
TRANSMISSION SYSTEMS AND MEDIA, DIGITAL SYSTEMS AND NETWORKS
INTERNATIONAL TELEPHONE CONNECTIONS AND CIRCUITS G.100G.199
GENERAL CHARACTERISTICS COMMON TO ALL ANALOGUE CARRIER-TRANSMISSION SYSTEMS
G.200G.299
INDIVIDUAL CHARACTERISTICS OF INTERNATIONAL CARRIER TELEPHONESYSTEMS ON METALLIC LINES G.300G.399
GENERAL CHARACTERISTICS OF INTERNATIONAL CARRIER TELEPHONE SYSTEMSON RADIO-RELAY OR SATELLITE LINKS AND INTERCONNECTION WITH METALLICLINES
G.400G.449
COORDINATION OF RADIOTELEPHONY AND LINE TELEPHONY G.450G.499
TRANSMISSION MEDIA AND OPTICAL SYSTEMS CHARACTERISTICS G.600G.699
DIGITAL TERMINAL EQUIPMENTS G.700G.799
DIGITAL NETWORKS G.800G.899
DIGITAL SECTIONS AND DIGITAL LINE SYSTEM G.900G.999
General G.900G.909
Parameters for optical fibre cable systems G.910G.919
Digital sections at hierarchical bit rates based on a bit rate of 2048 kbit/s G.920G.929
Digital line transmission systems on cable at non-hierarchical bit rates G.930G.939Digital line systems provided by FDM transmission bearers G.940G.949
Digital line systems G.950G.959
Digital section and digital transmission systems for customer access to ISDN G.960G.969
Optical fibre submarine cable systems G.970G.979
Optical line systems for local and access networks G.980G.989
Access networks G.990G.999
QUALITY OF SERVICE AND PERFORMANCE GENERIC AND USER-RELATEDASPECTS
G.1000G.1999
TRANSMISSION MEDIA CHARACTERISTICS G.6000G.6999
DATA OVER TRANSPORT GENERIC ASPECTS G.7000G.7999
PACKET OVER TRANSPORT ASPECTS G.8000G.8999
ACCESS NETWORKS G.9000G.9999
For further details, please refer to the list of ITU-T Recommendations.
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Recommendation ITU-T G.984.1
Gigabit-capable passive optical networks (GPON): General characteristics
Summary
Recommendation ITU-T G.984.1 describes a flexible optical fibre access network capable of
supporting the bandwidth requirements of business and residential services and covers systems with
nominal line rates of 2.4 Gbit/s in the downstream direction and 1.2 Gbit/s and 2.4 Gbit/s in the
upstream direction. Both symmetrical and asymmetrical (upstream/downstream) gigabit-capable
passive optical network (GPON) systems are described. This Recommendation proposes the general
characteristics for GPON based on operators' service requirements.
Source
Recommendation ITU-T G.984.1 was approved on 29 March 2008 by ITU-T Study Group 15
(2005-2008) under Recommendation ITU-T A.8 procedure.
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FOREWORD
The International Telecommunication Union (ITU) is the United Nations specialized agency in the field of
telecommunications, information and communication technologies (ICTs). The ITU Telecommunication
Standardization Sector (ITU-T) is a permanent organ of ITU. ITU-T is responsible for studying technical,
operating and tariff questions and issuing Recommendations on them with a view to standardizingtelecommunications on a worldwide basis.
The World Telecommunication Standardization Assembly (WTSA), which meets every four years,
establishes the topics for study by the ITU-T study groups which, in turn, produce Recommendations on
these topics.
The approval of ITU-T Recommendations is covered by the procedure laid down in WTSA Resolution 1.
In some areas of information technology which fall within ITU-T's purview, the necessary standards are
prepared on a collaborative basis with ISO and IEC.
NOTE
In this Recommendation, the expression "Administration" is used for conciseness to indicate both a
telecommunication administration and a recognized operating agency.
Compliance with this Recommendation is voluntary. However, the Recommendation may contain certain
mandatory provisions (to ensure e.g. interoperability or applicability) and compliance with the
Recommendation is achieved when all of these mandatory provisions are met. The words "shall" or some
other obligatory language such as "must" and the negative equivalents are used to express requirements. The
use of such words does not suggest that compliance with the Recommendation is required of any party.
INTELLECTUAL PROPERTY RIGHTS
ITU draws attention to the possibility that the practice or implementation of this Recommendation may
involve the use of a claimed Intellectual Property Right. ITU takes no position concerning the evidence,
validity or applicability of claimed Intellectual Property Rights, whether asserted by ITU members or others
outside of the Recommendation development process.
As of the date of approval of this Recommendation, ITU had not received notice of intellectual property,
protected by patents, which may be required to implement this Recommendation. However, implementers
are cautioned that this may not represent the latest information and are therefore strongly urged to consult the
TSB patent database athttp://www.itu.int/ITU-T/ipr/.
ITU 2009
All rights reserved. No part of this publication may be reproduced, by any means whatsoever, without the
prior written permission of ITU.
ii Rec. ITU-T G.984.1 (03/2008)
http://www.itu.int/ITU-T/ipr/http://www.itu.int/ITU-T/ipr/http://www.itu.int/ITU-T/ipr/http://www.itu.int/ITU-T/ipr/ -
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CONTENTS
Page
1 Scope
1
2 References
1
3 Definitions
2
3.1 Terms defined elsewhere
..........................................................................................................................
..........................................................................................................................
23.2 Terms defined in this Recommendation
..........................................................................................................................
..........................................................................................................................
2
4 Abbreviations and acronyms
3
5 Architecture of the optical access network
45.1 Network architecture
..........................................................................................................................
..........................................................................................................................
4
5.2 Reference configuration
..........................................................................................................................
..........................................................................................................................
5
6 Services, user-network interface and service node interface
6
6.1 Services
..........................................................................................................................
..........................................................................................................................
6
6.2 User-network interface (UNI) and service node interface (SNI)
..........................................................................................................................
..........................................................................................................................
7
7 Bit rate
7
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8 Logical reach
7
9 Physical reach
7
10 Differential fibre distance
7
11 Maximum mean signal transfer delay
7
12 Split ratio
7
13 Service overlay
8
14 Protection on the PON section
8
14.1 Possible switching types
..........................................................................................................................
..........................................................................................................................
8
14.2 Possible duplex GPON configurations and characteristics
..........................................................................................................................
..........................................................................................................................
9
14.3 Requirements
..........................................................................................................................
..........................................................................................................................
10
14.4 Required information fields for OAM frame
..........................................................................................................................
..........................................................................................................................
11
15 Security
11
Appendix I Examples of GPON services, architectures and service protocol stacks
12
I.1 Services, UNIs and SNIs
..........................................................................................................................
..........................................................................................................................
12
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I.2 Typical system architectures
..........................................................................................................................
..........................................................................................................................
14
I.3 Service protocol stacks
..........................................................................................................................
..........................................................................................................................16
Appendix II External access network backup
27
Appendix III Dual-parenting resilience
30
Bibliography
32
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Recommendation ITU-T G.984.1
Gigabit-capable passive optical networks (GPON): General characteristics
1 Scope
This Recommendation addresses the general characteristics of gigabit-capable passive opticalnetwork (GPON) systems in order to guide and motivate the physical layer and the transmission
convergence layer specifications. The general characteristics include examples of services,
user-network interfaces (UNIs) and service node interfaces (SNIs) that are requested by network
operators. Also, this Recommendation shows the principle deployment configuration.
As much as possible, this Recommendation maintains characteristics from [ITU-T G.982] and ITU-T
G.983.x-series Recommendations. This is to promote backward-compatibility with existing optical
distribution networks (ODNs) that complies with those Recommendations.
GPON systems are characterized, in general, by an optical line termination (OLT) system and an
optical network unit (ONU) or optical network termination (ONT) with a passive optical distribution
network (ODN) interconnecting them. There is, in general, a one-to-many relationship between the
OLT and the ONU/ONTs, respectively.
2 References
The following ITU-T Recommendations and other references contain provisions which, through
reference in this text, constitute provisions of this Recommendation. At the time of publication, the
editions indicated were valid. All Recommendations and other references are subject to revision;
users of this Recommendation are therefore encouraged to investigate the possibility of applying the
most recent edition of the Recommendations and other references listed below. A list of the currently
valid ITU-T Recommendations is regularly published. The reference to a document within this
Recommendation does not give it, as a stand-alone document, the status of a Recommendation.
[ITU-T G.652] Recommendation ITU-T G.652 (2003), Characteristics of a single-mode optical
fibre cable.
[ITU-T G.808.1]Recommendation ITU-T G.808.1 (2006), Generic protection switching Linear trail
and subnetwork protection.
[ITU-T G.902] Recommendation ITU-T G.902 (1995),Framework Recommendation on
functional access networks (AN) Architecture and functions, access types,
management and service node aspects.
[ITU-T G.982] Recommendation ITU-T G.982 (1996), Optical access networks to support
services up to the ISDN primary rate or equivalent bit rates.
[ITU-T G.983.1]Recommendation ITU-T G.983.1 (1998),Broadband optical access systems based
on Passive Optical Networks (PON).
[ITU-T G.983.2]Recommendation ITU-T G.983.2 (2002), ONT management and control interface
specification for B-PON.
[ITU-T G.983.3]Recommendation ITU-T G.983.3 (2001),A broadband optical access system with
increased service capability by wavelength allocation.
[ITU-T G.984.2] Recommendation ITU-T G.984.2 (2003), Gigabit-capable Passive Optical
Networks (GPON): Physical Media Dependent (PMD) layer specification.
[ITU-T G.984.3] Recommendation ITU-T G.984.3 (2008), Gigabit-capable Passive Optical
Networks (GPON): Transmission convergence layer specification.
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[ITU-T G.984.4] Recommendation ITU-T G.984.4 (2008), Gigabit-capable Passive Optical
Networks (GPON): ONT management and control interface specification.
[ITU-T G.984.5] Recommendation ITU-T G.984.5 (2007), Gigabit-capable Passive Optical
Networks (GPON): Enhancement band.
[ITU-T I.112] Recommendation ITU-T I.112 (1993), Vocabulary of terms for ISDNs.
3 Definitions
This Recommendation makes frequent use of the terms defined in [ITU-T G.983.1] and
[ITU-T G.983.3]; some terms have been added. For convenience, the main definitions related to the
GPON service requirements are reported in this clause.
3.1 Terms defined elsewhere
This Recommendation uses the following terms defined elsewhere:
3.1.1 service node interface(SNI): [ITU-T G.902]
3.1.2 user-network interface(UNI): [ITU-T I.112]
3.2 Terms defined in this Recommendation
This Recommendation defines the following terms:
3.2.1 adaptation function (AF): AF is additional equipment and/or function to change an
ONT/ONU subscriber-side interface into the UNI. Functions of AF depend on the ONT/ONU
subscriber-side interface and UNI interface. AF is also used to change an OLT network interface into
the SNI interface that is required by an operator.
3.2.2 differential fibre distance: An OLT is connected to several ONU/ONTs. The differential
fibre distance is the difference in the distance between the nearest and furthest ONU/ONT from the
OLT.
3.2.3 logical reach: Logical reach is defined as the maximum distance that can be achieved for a
particular transmission system, regardless of the optical budget.
3.2.4 mean signal transfer delay: The mean signal transfer delay is the average of the upstream
and downstream delay values between reference points; this value is determined by measuring round-
trip delay and then dividing by 2.
3.2.5 optical access network (OAN): The OAN is the set of access links sharing the same
network-side interfaces and supported by optical access transmission systems. The OAN may include
a number of ODNs connected to the same OLT.
3.2.6 optical distribution network (ODN): In the PON context, a tree of optical fibres in theaccess network, supplemented with power or wavelength splitters, filters or other passive optical
devices.
3.2.7 optical line termination (OLT): A device that terminates the common (root) endpoint of an
ODN, implements a PON protocol, such as that defined by [ITU-T G.984], and adapts PON PDUs for
uplink communications over the provider service interface. The OLT provides management and
maintenance functions for the subtended ODN and ONUs.
3.2.8 optical network termination (ONT): A single subscriber device that terminates any one of
the distributed (leaf) endpoints of an ODN, implements a PON protocol, and adapts PON PDUs to
subscriber service interfaces. An ONT is a special case of an ONU.
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3.2.9 optical network unit (ONU): A generic term denoting a device that terminates any one of
the distributed (leaf) endpoints of an ODN, implements a PON protocol, and adapts PON PDUs to
subscriber service interfaces. In some contexts, an ONU implies a multiple-subscriber device.
3.2.10 physical reach: Physical reach is defined as the maximum physical distance that can be
achieved for a particular transmission system.
3.2.11 service: Service is defined as a network service required by operators. Service is described bya name that is clearly recognized by everyone, regardless of whether it is a frame structure name or a
general name.
4 Abbreviations and acronyms
This Recommendation uses the following abbreviations and acronyms:
AF Adaptation Function
BRI Basic Rate Interface
DSL Digital Subscriber Line
FTTB Fibre to the Building
FTTC Fibre to the Curb
FTTCab Fibre to the Cabinet
FTTH Fibre to the Home
ISDN Integrated Services Digital Network
LT Line Terminal
MDU Multi-Dwelling Unit
NT Network TerminationOAM Operation, Administration and Maintenance
OAN Optical Access Network
ODN Optical Distribution Network
OLT Optical Line Termination
ONT Optical Network Termination
ONU Optical Network Unit
OpS Operations System
PDH Plesiochronous Digital Hierarchy
PON Passive Optical Network
POTS Plain Old Telephone Service
PRI Primary Rate Interface
PSTN Public Switched Telephone Network
SDH Synchronous Digital Hierarchy
SN Serial Number
SNI Service Node InterfaceTC Transmission Convergence
UNI User-Network Interface
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VOD Video On Demand
WDM Wavelength Division Multiplexing
5 Architecture of the optical access network
5.1 Network architecture
The optical section of a local access network system can be either active or passive and its
architecture can be either point-to-point or point-to-multipoint. Figure 1 shows the architectures
considered, which range from fibre to the home (FTTH), through fibre to the building/curb (FTTB/C)
to fibre to the cabinet (FTTCab). The optical access network (OAN) is common to all architectures
shown in Figure 1, hence the commonality of this system has the potential to generate large
worldwide volumes.
G.984.1_F1
Fibre
Fibre
Fibre
Copper
Copper
Access networkHome
network
UNI SNI
ONU Optical Network Unit
ONT Optical Network Termination
OLT Optical Line Termination
NT Network Termination
FTTCab
FTTH
O
NT
NT
NT
ONU
ON
U
OLT
FTTB/C
Figure 1 Network architecture
The differences of the FTTB, FTTC, FTTCab and FTTH network options are mainly due the different
services supported, so they can be treated the same in this Recommendation.
5.1.1 FTTB scenario
The FTTB scenario is divided into two scenarios, one for multi-dwelling units (MDUs) and the other
for businesses. Each scenario has the following service categories.
5.1.1.1 FTTB for MDU
Asymmetric broadband services (e.g., digital broadcast services, VOD, file download, etc.).
Symmetric broadband services (e.g., content broadcast, e-mail, file exchange, distance
learning, telemedicine, online-gaming, etc.).
POTS and ISDN. The access network must be able to provide, in a flexible way, narrow-band
telephone services with appropriate timing for the introduction.
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5.1.1.2 FTTB for business
Symmetric broadband services (e.g., group software, content broadcast, e-mail, file exchange,
etc.).
POTS and ISDN. The access network must be able to provide, in a flexible way, narrow-band
telephone services with the appropriate timing for the introduction.
Private line services. The access network must be able to provide, in a flexible way, privateline services at several rates.
5.1.2 FTTC and FTTCab scenario
Within this scenario, the following service categories have been considered:
Asymmetric broadband services (e.g., digital broadcast services, VOD, file download, online-
gaming, etc.).
Symmetric broadband services (e.g., content broadcast, e-mail, file exchange, distance
learning, telemedicine, etc.).
POTS and ISDN. The access network must be able to provide, in a flexible way, narrow-band
telephone services with the appropriate timing for the introduction. xDSL backhaul.
5.1.3 FTTH scenario
Within this scenario, the following service categories have been considered:
Asymmetric broadband services (e.g., digital broadcast services, VOD, file download, etc.).
Symmetric broadband services (e.g., content broadcast, e-mail, file exchange, distance
learning, telemedicine, online-gaming, etc.).
POTS and ISDN. The access network must be able to provide, in a flexible way, narrow-band
telephone services with the appropriate timing for the introduction.
5.2 Reference configuration
The reference configuration is shown in Figure 2.
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G.984.1_F2
Q
UNI
R/S
S/R
SNI
V reference pointT Reference point
AccessNetworkSystem Management Functions
Optical Splitter OLT
WDM
NE
WDM
AF
NE
ODN
POINT A
POINT B
(a) Reference point
Optical Network Unit
Optical Network Terminal
Optical Distribution Network
Optical Line TerminationWavelength Division Multiplex Module (If WDM is not used, this function is not necessary.)
Network Element which uses the different wavelength from the OLT and the ONU
Adaptation Function (Sometimes, it may be included in the ONU.)
Service Node Interface
User Network Interface
Point on the optical fibre just after the OLT (Downstream)/ONU (Upstream) optical connection
point (i.e., optical connector or optical splice)
Point on the optical fibre just before the ONU (Downstream)/OLT (Upstream) optical connection
point (i.e., optical connector or optical splice)
If AF is included in the ONU, this point is not necessary.
If WDM is not used, these points are not necessary.
ONU
ONT
ODN
OLTWDM
NE
AF
SNI
UNI
S
R
(a) Reference point
POINT A/B
Servicenode
function
ONU/ONT
IFPONIFPON
NOTE Whether or not the AF is an operating object of the Q interface depends on the service.
Figure 2 Reference configuration for GPON
5.2.1 Service node interface
See [ITU-T G.902].
5.2.2 Interface at the reference points S/R and R/S
The interface at reference points S/R and R/S is defined as IFPON.This is a PON-specific interface that
supports all the protocol elements necessary to allow transmission between OLT and ONUs.
6 Services, user-network interface and service node interface
6.1 Services
GPON is required to support all currently known services and new services being discussed for
residential subscribers and business customers, because of such a broadband capability.
What specific services should be provided is clearer to some operators than to others and depends
heavily on the particular regulatory conditions of each operator's markets, as well as on the market's
own potential. How these services are delivered in a cost-effective way is a function not only of legal
conditions, but also of factors including existing telecommunication infrastructure, dwelling
distribution, and residential and business customers mix.
Some examples of services are described in clause I.1.
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6.2 User-network interface (UNI) and service node interface (SNI)
ONU/ONT has UNI, as well as OLT, has an SNI as described in Figure 2. UNI/SNI depends on
which services are provided by the service operator.
Some examples of UNI are described in clause I.2 and examples of SNI are described in clause I.3.
7 Bit rate
Basically, GPON aims at transmission speeds greater than or equal to 1.2 Gbit/s. Accordingly, GPON
identifies two transmission speed combinations as follows:
1.2 Gbit/s up, 2.4 Gbit/s down;
2.4 Gbit/s up, 2.4 Gbit/s down.
The most important bit rate is 1.2 Gbit/s up, 2.4 Gbit/s down, constituting nearly all of the deployed
and planned deployment of the GPON systems.
8 Logical reach
Logical reach is the maximum distance between ONU/ONT and OLT except for the limitation of the
physical layer. In GPON, the maximum logical reach is defined as 60 km.
9 Physical reach
Physical reach is the maximum physical distance between the ONU/ONT and the OLT. In GPON,
two options are defined for the physical reach: 10 km and 20 km. It is assumed that 10 km is the
maximum distance over which FP-LD can be used in the ONU for high bit rates such as 1.25 Gbit/s
or above.
10 Differential fibre distanceIn GPON, the maximum differential fibre distance is 20 km. This affects the size of the ranging
window and provides compliance with [ITU-T G.983.1].
11 Maximum mean signal transfer delay
GPON must accommodate services that require a maximum mean signal transfer delay of 1.5 ms.
Specifically, GPON system must have a maximum mean signal transfer delay time of less than 1.5 ms
between T-V (or (a)-V, depending on the operator's preference). See clause 12 of [ITU-T G.982].
Delays introduced by the adaptation functions such as circuit emulation are not included in this value.
Although a section of the delay measurement is T-V for FTTH system, or (a)-V for the otherapplication in [ITU-T G.982], in a GPON system the reference points are not restricted by the system
configuration.
12 Split ratio
Basically, the larger the split ratio is for GPON, the more attractive it is for operators. However, a
larger split ratio implies greater optical splitting which creates the need for an increased power budget
to support the physical reach.
Split ratios of up to 1:64 are realistic for the physical layer, given current technology. However,
anticipating the continued evolution of optical modules, the TC layer must consider split ratios up
to 1:128.
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13 Service overlay
An overlay wavelength may be used to provide enhanced services to the subscriber. Accordingly,
GPON must vacate the Enhancement Band defined in [ITU-T G.983.3].
14 Protection on the PON section
From the viewpoint of administration of the access network, the protection architecture of GPON isconsidered to enhance the reliability of the access networks. However, protection shall be considered
as an optional mechanism because its implementation depends on the realization of economical
systems. Further information on protection switching can be found in [ITU-T G.808.1].
This clause presents some possible duplex configurations and related requirements as examples of
protected GPON systems. In addition, the required OAM message for protection is mentioned.
14.1 Possible switching types
There are two types of protection switching, both of which are analogous to those of SDH systems:
i) automatic switching; and
ii) forced switching.
The first type is triggered by fault detection, such as loss of signal, loss of frame, signal degrade (BER
becomes worse than the predetermined threshold), and so on. The second type is activated by
administrative events, such as fibre rerouting, fibre replacement, etc. Both types should be possible in
a GPON system, if required, even though they are optional functions. The switching mechanism is
generally realized by the OAM function, therefore, the required OAM information field should be
reserved in the OAM frame.
Figure 3a shows the self-contained duplex system model for the access network. The relevant part of
the protection in the GPON system in this scheme should be a part of the protection between the ODN
interface in the OLT and the ODN interface in the ONU via the ODN, excluding the SNI redundancyin the OLT.
G.984.1_F3
PON LT(1)
PON LT(0)
PON LT(1)
PON LT(0)
Switch
SNI LT(1)
SNI LT(0)ODN(0)
ODN(1)
S/R R/S
ONU
OLT
UNI
LT
Servicenode
MUX
Figure 3a Duplex system model
Figure 3b shows the duplex system model for the dual-parented access network. The relevant part of
the protection in the GPON system should be a part of the protection between the ODN interface in
the ONU and each ODN interface in the two OLTs via the ODN, plus the signalling required to
implement protection functions upstream from the SNI.
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PON LT(1)
PON LT(0)
PON LT(1)
M
U
X
UNI
LT
Switch SNI LT(1)
PON LT(0) Switch SNI LT(0)
ODN(1)
S/R R/S
ONU
OLT
OLT
ODN(0)
Network
PON LT(1)
PON LT(0)
PON LT(1)PON LT(1)
M
U
X
M
U
X
UNI
LT
UNI
LT
SwitchSwitch SNI LT(1)SNI LT(1)
PON LT(0)PON LT(0) Swi tchSwitch SNI LT(0)SNI LT(0)
ODN(1)
S/R R/S
ONU
OLT
OLT
ODN(0)
NetworkNetwork
Figure 3b Dual-parented duplex system model
14.2 Possible duplex GPON configurations and characteristics
There can be several types of duplex GPON systems, as shown in Figures 4a and 4b. The control
protocols for each configuration should be specified independently from one another.
For example, in Figure 4b, no switching protocol is required since the switching is carried out only in
the OLT.
14.2.1 Configuration examples
Type A: A deprecated configuration that duplicated only the optical fibres.
Type B: The second configuration (Figure 4a) doubles the OLTs and the optical fibres between the
OLTs and the optical splitter, and the splitter has two input/output ports on the OLT side. This
configuration reduces the cost of duplexing the ONUs, although only the OLT side can be recovered.Type C: The third configuration (Figure 4b) doubles not only the OLT side facilities but also the
ONU side. In this configuration, recovery from failure at any point is possible by switching to the
standby facilities. Therefore, the full duplex cost enables high reliability.
Type D: A deprecated configuration that allowed the mixing of duplicated and non-duplicated ONUs,
essentially providing a combination of types B and C protection.
G.984.1_F4b
ONU #1
ONU #N
OLT
PON LT
PON LT
PON LT(0)
PON LT(1)
N:2 optical splitter
Figure 4a Duplex GPON system: OLT-only duplex system
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G.984.1_F4c
PON LT(0)
PON LT(1)
PON LT(0)
PON LT(1)
OLT
PON LT(0)
PON LT(1)
ONU #1
ONU #N
DoubleN:2 optical splitter
Figure 4b Duplex GPON system: Full duplex system
Note that in both of these types of protection schemes, the PON line terminations do not need to
reside in a single OLT equipment. In fact, they may be located in physically diverse locations (dual
parenting). The control of such a system is discussed in Appendix III.
14.2.2 Characteristics
Type B: This configuration requires cold standby of the spare circuit in the OLT side. In this case,
signal loss or even frame loss is, in general, inevitable in the switching period. However, all the
connections supported between the service node and the terminal equipment should be held after thisswitching.
Type C: In this case, the hot standby of the spare receiver circuits is possible in both ONU and OLT
sides. In addition, hitless switching (without frame loss) is also possible in this configuration.
14.3 Requirements
1) The protection switching function should be optional.
2) Both automatic protection switching and forced switching are possible in the GPON system,
if required, even though they are optional functions.
3) All the configuration examples of clause 14.2 will be possible, even though they are optional
functions.
4) The switching mechanism is generally realized by the OAM function, therefore, the required
OAM information field must be reserved in the OAM frame.
5) All the connections supported between the service node and the terminal equipment should
be held after switching.
Regarding the last requirement, one implementation of the POTS service node (exchange) requires
the frame loss period to be less than 120 ms. If the frame loss period becomes longer than that, the
service node disconnects the call, and the call set-up is required again after the protection switching.
Since GPON supports the emulation of conventional services, such as POTS and ISDN, this value
should be taken into consideration.T1 and E1 services require 50 ms protection times, so for these services to be provided as protected,
the GPON should support 50 ms protection times.
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14.4 Required information fields for OAM frame
Protection switching requires less than ten codes to be used for both upstream and downstream, which
will be realized by the field of the OAM frame. The field mapping of the OAM frame for the
protection will be required to be defined.
15 SecurityDue to the multicast nature of the PON, GPON needs a security mechanism adapting the following
requirements:
To prevent other users from easily decoding the downstream data.
To prevent other users from masquerading as another ONU/ONT or user.
To allow cost-effective implementation.
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Appendix I
Examples of GPON services, architectures and service protocol stacks
(This appendix does not form an integral part of this Recommendation)
This appendix provides various examples of practical GPON system aspects. First, a review of the
typical services a GPON system supports is given. Second, a selection of system architectures are
illustrated. Third, the common protocol stack traces are laid out for all these services and systems.
It should be noted that since GPON is so widely applicable, the total scope of all the variants is very
large, and any single implementation will not implement all of the possible features. The object of this
appendix is to only give a general overview for the family of systems.
I.1 Services, UNIs and SNIs
This clause describes some examples of services, UNI and SNI, which are required by operators.
I.1.1 Examples of services
Some examples of services that GPON are required to support are shown in Table I.1, along with
relevant remarks.
Table I.1 Examples of services and related remarks
Service category
(Note 1)Service Remarks
Data service Ethernet
(Note 2)
Standardized in [b-IEEE 802.3].
Comply with [b-IEEE 802.1D].
PSTN POTS Mean signal transfer delay time between T-V (or (a)-V) should be less
than 1.5 ms. If echo cancellation is used in the network, the mean
signal transfer delay time between T-V (or (a)-V) on the PON-based
system may be longer, provided end-to-end transfer delay
requirements are met.
Synchronize with the network clock (Note 3).
Signal on the T reference point and V reference point must be
continuous.
ISDN (BRI) Bearer rate is 144 kbit/s.
Mean signal transfer delay time between T-V (or (a)-V) should be less
than 1.5 ms.
Synchronize with the network clock (Note 3).
ISDN (PRI) Bearer rate is 1.544 Mbit/s and 2.048 Mbit/s.
Mean signal transfer delay time between T-V (or (a)-V) should be less
than 1.5 ms.
Synchronize with the network clock (Note 3).
Private Line T1 Bearer rate is 1.544 Mbit/s.
Mean signal transfer delay time between T-V (or (a)-V) should be lessthan 1.5 ms.
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Table I.1 Examples of services and related remarks
Service category
(Note 1)Service Remarks
E1 Bearer rate is 2.048 Mbit/s.
Mean signal transfer delay time between T-V (or (a)-V) should be less
than 1.5 ms.
DS3 Bearer rate is 44.736 Mbit/s.
E3 Bearer rate is 34.368 Mbit/s.
Video Digital video Primary focus is on video over IP, with a QoS sufficient to support
competitive viewing experience as compared to traditional transport
methods.
NOTE 1 Service category is merely an index. It is not meaningful in itself, but it is useful in visualizing
the services.
NOTE 2 Ethernet service is mainly to transmit data such as IP, which includes VoIP, video streams
coded by MPEG-2 or MPEG-4, and so on.
NOTE 3 See [b-ITU-T G.810], [b-ITU-T G.813], [b-ITU-T G.8261], [b-ITU-T G.703] and
[b-ITU-T G.8262].
I.1.2 Examples of UNI
In this appendix, UNI is defined as the interface that includes the following conditions:
described by a well-known standard;
includes a physical layer aspect.
Some UNIs are provided via an AF, so it is not mandatory that the ONU/ONT support those
interfaces.
Examples of UNIs, physical interfaces and services that they provide are shown in Table I.2.
Table I.2 Examples of UNI and services
UNI (Note 1)Physical interface (Note
2)Service (Note 3)
10BASE-T ([b-IEEE 802.3]) Ethernet
100BASE-TX ([b-IEEE 802.3]) Ethernet
1000BASE- T ([b-IEEE 802.3]) Ethernet
[b-ITU-T I.430] ISDN (BRI)
[b-ITU-T G.703] PDH DS3, ATM, E1, E3
[b-ANSI T1.102],
[b-ANSI T1.107]
PDHT1, DS3
NOTE 1 There are many other services accommodated in GPON, but those services do not have
specified UNIs.
NOTE 2 Each item in the "physical interface" column is illustrated by the corresponding entry in the
"UNI" column.
NOTE 3 The column labelled "service" shows which services can be supported by the physical interface.
I.1.3 Examples of SNI
In this appendix, SNI is defined as the interface that includes the following conditions:
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described by a well-known standard;
includes a physical layer aspect.
Examples of SNIs, physical interfaces and services that they provide are shown in Table I.3.
Table I.3 Examples of SNI and services
SNI
(Note 1)
Physical interface
(Note 2)
Service
(Note 3)
1000BASE ([b-IEEE 802.3])
10000BASE ([b-IEEE 802.3])
Ethernet
[b-ITU-T G.965] V5.2 POTS, ISDN(BRI), ISDN(PRI)
[b-ITU-T G.703] PDH, STM-1e DS3, ATM, E1, E3, STM-1, DS1
[b-ITU-T G.957] STM-1, 4, 16 E1, E3, DS1, DS3, GFP, E4, STM-n,
ATM
[b-ANSI T1.107] PDH DS1, DS3
[b-ANSI T1.105.06]
[b-ANSI T1.117]
OC3, OC12 DS1, DS3, ATM
NOTE 1 There are many other services accommodated in GPON, but those services do not have
specified SNIs.
NOTE 2 Each item in the "physical interface" column is illustrated by the corresponding entry in the
"SNI" column.
NOTE 3 The column labelled "service" shows which services can be supported by the physical interface.
I.2 Typical system architectures
Figure I.1 shows a generic GPON system. This is developed more specifically in Figures I.2 to I.7.
OLT
ONU
/
ONT
ODN
CPESNI(s) UNI(s)
Figure I.1 Generic GPON system
I.2.1 OLT variants
Figure I.2 shows a pure-OLT option. In this case, the OLT equipment contains only the GPON
adaptation function, and typically (but not necessarily) some level of Ethernet aggregation function. It
is the simplest form of OLT, and avoids as many specific service linkages as possible.
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OLT
ONU
/
ONT
ODN
CPESNI UNI(s)
Ether
Figure I.2 Pure OLT scenario
Figure I.3 shows a grooming OLT scenario. In this case, the OLT takes on additional
service-grooming functions, typically including voice gateway and TDM circuit emulation functions.
Note that these services can be provided using a 'pure OLT' and a separate voice gateway; however,
as a practical matter, the integration of voice and TDM services seems to have strong economic andpractical advantages.
OLTONU
/
ONT
ODN
CPESNI UNI(s)
DS1
Ether
Figure I.3 Grooming OLT scenario
I.2.2 ONU variants
Figure I.4 shows the 'VDSL/POTS ONU' variant. The distinguishing feature of this variation is that
the ONU is used to create copper-based interfaces just like a digital loop carrier/digital subscriber line
access multiplexer (DLC/DSLAM) would do. There are two sub-types of this scheme. The first is
where the ONU provides both POTS and VDSL interfaces to the customer, trying to centralizefunctions and reduce the need for CPE. The second is where the ONU provides VDSL-only
interfaces, trying to minimize the ONU's size and power, albeit at the cost of requiring POTS
derivation at the CPE. This alternative is useful mostly in FTTB and FTTC applications.
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OLT ONUODN
CPESNI(s) UNI(s)
CPE UNI(s)DSL
POTS
Figure I.4 VDSL/POTS ONU scenario
Figure I.5 shows the 'GPON modem' variant, where the ONT is made as small and simple as possible.In this case, it resembles a modem that provides Layer 1 and 2 interworking between the GPON
optical interface and the data link technology. The data link then carries all service flows to the CPE,
which does the bulk of the service interworking function. The popular data link technologies in use
today are CAT5-based Ethernet, HPNA-over-coax and MoCA. This system is mostly used in FTTH
applications.
OLT ONTODN CPESNI(s) UNI(s)
Data
Link
Figure I.5 GPON modem scenario
Figure I.6 shows the 'integrated ONT' situation. This is can be thought of as the merger of the GPONmodem and the service-deriving CPE in the previous diagram. However, this merging of functions
has critical implications on which system is responsible for the management of the services. It should
also be noted that even though significant functions have been incorporated into the ONT, a CPE is
typically still placed in the home. This scenario is also popular for FTTH.
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OLT ONTODNSNI(s)
CPEUNI(s)
Figure I.6 Integrated ONT scenario
Figure I.7 shows the 'residential gateway ONT' situation. This is can be thought of as the merger of
the integrated ONT and the service-deriving CPE in the previous diagram. This draws Layer 3
functionality into the ONT, including such items as routing, NAT and firewall functionality. This
scenario is also popular for FTTH.
OLT ONTODNSNI(s) UNI(s)
Figure I.7 Residential gateway ONT scenario
I.3 Service protocol stacksThe following clauses present a listing of protocol stacks for the important service traces in GPON
systems. By service, we mean the basic Layer 2-3 interfaces that have a major impact on the GPON
equipment. Many high-layer services can ride on top of these interfaces; however, they tend not to
have such a concrete impact on the GPON equipment, or at least not an impact any different than any
other access system.
I.3.1 Common functions
The common GPON layers are shown in Figure I.8. [ITU-T G.984.2] specifies the GPON physical
medium and the physical medium dependents (optics). [ITU-T G.984.4] defines the transmission
convergence layer, which deals primarily with the construction of the transmission frame and the
encapsulation of payload datagrams inside GPON encapsulation method (GEM) fragments. There is awealth of other auxiliary features described in [ITU-T G.984.3], including the PLOAM channel,
dynamic bandwidth allocation, and the PON-level QoS frameworks, that are possible.
It should be noted that the DBA algorithm is not specified in any standard, but this is not an
interoperability issue, and the non-specification has been intentional.
The QoS system in GPON defines a scheme where each ONT may contain one or more transmission
container(s) (T-CONTs). Each T-CONT may contain one or more GEM ports, which are the smallest
connection that GPON systems handle. [ITU-T G.984.3] leaves the arrangement of T-CONT and
GEM ports open. The mainstream arrangement is four service-bearing T-CONTs per ONT, with each
representing a different class of service.
[ITU-T G.984.4] defines the ONT management and configuration interface (OMCI). It defines both a
management information base (MIB) for all the functions controlled in the ONT, as well as the ONT
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management communication channel (OMCC) that provides all the mechanisms required for the OLT
to provide FCAPS functionality for the ONT.
The OLT management is a somewhat more complex object. It contains by proxy all the MIBs of all
the ONUs supported by that OLT, as well as all the other MIBs that describe the other functions in the
OLT. This MIB is defined by several standards groups, including the Internet Engineering Task Force
(IETF) and the TM forum. Typically, these MIBs are accessed using standard IETF-defined protocols
(SNMP over TCP/IP). Most OLTs provide a dedicated Ethernet interface for this management traffic.
All of the functions mentioned above are common functions, involved in all of the service traces that
follow. They will be more compactly represented in the later diagrams for the sake of brevity.
TMF,
IETF
PON Medium
G.984.3
G.984.2
PMDPMD
Eth. PMD TCTC
OMCCOMCC
G.984.4
TCP/IP
Eth. MAC
OLT MIB.
ONU MIB
802.3
SNMP
IETF
QoSDBA
Figure I.8 GPON common functions
The GPON real-time clock service is shown in Figure I.9. The OLT receives real-time clock data via
NTP, typically over an Ethernet interface via UDP over IP. The OLT thereby maintains its own
internal RTC, which it uses to timestamp all manner of event data.
The ONT does not extend this RTC. Rather, its performance-monitoring and event-collectionprocesses are synchronized with those of the OLT via the OMCI. The OLT routinely collects all of
this data every 15 minutes and logs it with the OLT RTC.
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PON Medium
G.984.3
G.984.2
PMDPMD
Eth. PMD TCTC
OMCC
UDP/IP
Eth. MAC
OLT RTC
ONU MIB
802.3
NTP
IETF
OMCC
Figure I.9 Real-time clock service
The GPON network clock scheme is shown in Figure I.10. The OLT needs to obtain a high quality
traceable timing clock, which serves as the master for all GPON interface timing. The normal source
for the OLT's clock is a BITS timing input. However, in cases where a BITS source is not available,
then an alternative method is needed. The alternative could be synchronous line timing from an SNI
that is traceable to the network clock, or packet-based timing.
Once the OLT network clock is established, it is used to source timing to the GPON interfaces, which
in turn distribute timing to the counterpart ONT GPON interfaces. The ONT equipment then obtains
its network clock from the GPON interface. This timing signal is ideal for TDM service interworking
functions that are integrated into the ONT. Typically, this timing signal is not available to terminal
adapters. However, if the timing signal is provided to the terminal adapters, then the synchronous
Ethernet method is preferred.
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PON Medium
G.984.3
G.984.2
PMDPMD
Eth. PMD TCTC
UDP/IP
Eth. MAC
OLT network clock
802.3
Pkt timing
IETF ONTNetwork clock
G.8261
DS-1
Phy
DS-1framer
e.g.,
T1-107
BITS timing
Sync.timing
Figure I.10 Network clock service
I.3.2 Data functions
The layer diagram for Ethernet service is shown in Figure I.11. In the ONT, Ethernet frames as
defined in [b-IEEE 802.3] are extracted from the TC layer. In some ONTs, the Ethernet layer is quite
abbreviated and little processing is done on the frames from their reception on the GPON interface to
their transmission on the UNI. In other ONTs, true bridging is performed, with MAC address
processing and potentially more. In some cases, PPPoE (not shown) is supported; however, thisscheme seems to be waning.
In some ONTs, some sort of VLAN processing is done, as defined in the IEEE 802.1-series of
standards. Most systems use the 802.1ad version, where two layers of tags have been specified,
although some systems actually support up to four layers of tags to be applied. This typically involves
adding tag(s) in the upstream, and removing tag(s) in the downstream, for the purpose of identifying
each user/service packet via their VLAN-ID. However, this is not necessary in all cases, since the
PON itself has the GEM port-ID mechanism for such identification.
On the OLT side, the Ethernet frames are taken from the GPON, and in some cases they receive their
VLAN tags at the OLT (basically, swapping the GEM port-ID for an Ethernet VLAN tag). Then, in
nearly all equipment, the resulting frames are switched using an Ethernet switching matrix. Thisswitching can be on the basis of VLAN tags, or MAC addresses, or both. There are several
mainstream arrangements of VLANs; these are specified in [b-DSL TR-101]. The traffic then leaves
the OLT over some type of Ethernet interface, for connection to an edge routing device or other
Ethernet aggregation device.
It should be noted that there are several different interfaces that can take the place of an Ethernet Phy.
These include xDSL (e.g., see below), MoCA, HPNA, HPNA-over-coax, 802.11 Wi-Fi, and perhaps
others yet to be devised. However, due to Ethernet's pervasive nature, all of these alternative PHYs
are defined so that they operate in a way nearly the same as Ethernet, and so their impact on the
GPON system is rather small.
All of these ONT features are controlled via the OMCI, as defined in [ITU-T G.984.4].
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802.1 802.1
802.3
TR-101
Eth. PMD
G.984.4 (mgt)
Eth. MAC
VLAN switching
Eth. MAC Eth. MAC
Eth. PMD
Eth. MAC
802.3
VLAN tagging
PON Medium
G.984.3
G.984.2
PMDPMD
TCTC
IETF, TMF (mgt)
Figure I.11 Ethernet data service
The VDSL2 service is shown in Figure I.12. The first thing to be said is that the DSL type that is most
widely used for GPON is VDSL2 (defined in the ITU-T G.993-x series of Recommendations), using
packet transport mode. It is possible that ADSL2 plus or VDSL1 might be implemented for
compatibility reasons, however, it is not the main thrust of most GPON development. With this said,
the VDSL2 VTU-O function in the ONT operates much like an Ethernet PHY, and most of the layer
diagram is similar to that of an Ethernet service. There are important differences, the biggest of which
is the presence of multiple bearer channels in the same port. Each of these bearers would be treated as
a 'virtual PHY', and the overall system is still unchanged.
The management of the VTU-O located in the ONT is described in [ITU-T G.984.4].
802.1 802.1
802.3
TR-101
Eth. PMD
G.984.4 (mgt)
Eth. MAC
VLAN switching
Eth. MAC Eth. MAC
VDSL2
Eth. MAC 802.3
VLAN tagging
PON Medium
G.984.3
G.984.2
PMDPMD
TCTC
IETF, TMF (mgt)
G.993
Figure I.12 VDSL2 service
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Figure I.13 describes the multicast service. This is really a logical service, usually provided in
conjunction with an Ethernet UNI (or similar). However, it has an impact on the GPON system, so we
include it here. The multicasting interactive signalling is provided by the IETF IGMP, versions 2 or 3.
This IP-layer multicasting topology is typically translated into Ethernet-layer multicasting via the
trivial mapping defined in IEEE 802.1 standards. The management of multicasting, including the
eligibility of UNIs to receive multicast traffic, the GPON ports that contain the multicast traffic, and
their interconnection, is defined in [ITU-T G.984.4].
802.1 802.1
802.3
IGMPv2/3
Eth. PMD
G.984.4 (mgt)
Eth. MAC
Multicasting
Eth. MAC Eth. MAC
Eth. PMD
Eth. MAC
802.3
Multicasting
PON Medium
G.984.3
G.984.2
PMDPMD
TCTC
IETF, TMF (mgt)
Figure I.13 Multicast service
I.3.3 Voice functions
The packet-based voice service flow is pictured in Figure I.14. By packet voice service, we describe a
voice service that does not terminate on a class 5 TDM switch but instead is transported via an IP
network to its destination. The mainstream protocol system used in this scenario is SIP, running over
RTP/UDP/IP, all defined in IETF documents. This is easy to say, but because SIP-based VoIP aims to
replace the class 5 switching system, it must therefore implement the sizable set of voice service
features. A great deal of interoperability engineering must be done in any combination of VoIP-ONT
and softswitch.
The voice codecs are defined in the [b-ITU-T G.711], [b-ITU-T G.729], [b-ITU-T G.726], [b-ITU-T
G.723] family. It should be noted that while the majority of VoIP systems are actively exploring
advanced codecs for compression reasons, GPON is not concerned with this, since bandwidth is
plentiful. In contrast, the codec selection here is mainly driven by interoperability with the far end of
the SIP VoIP session.
The POTS UNI is defined for the large part by national standards (e.g., European operators use
[b-ETSI ETS 300 001]). However, it must be noted that POTS remains a very intricate service, and
many operators have special requirements on the POTS interface, particularly on the lowest-level
mechanical and electrical specifications of the metallic interface.
From the SIP agent in the ONT, the service flow traverses a path very similar to the standard Ethernet
service. VLAN tagging and Ethernet bridging may be applied at either the ONT, or OLT, or both. The
user traffic, both bearer and signalling, leaves the OLT via an Ethernet interface, usually shared with
other services.
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The management of the packet voice service is varied at present. [ITU-T G.984.4] provides a full
fault, configuration, accounting, performance-monitoring and security (FCAPS) support of SIP VoIP.
However, there are several other in-band systems that are in use, such as TR-69, IETF sipping, and
various proprietary configuration servers. These in-band systems are good in that they can manage
VoIP terminal adapters anywhere on a network, so they have a wide reach. However, most suffer
from poor practical standardization, and a lack of interactive features (such as the support of alarms
and performance management). To help address this last point, even when an in-band system is usedfor configuration of VoIP, the OMCI can still be used to gather alarms and PM information. This is
basically a mixed management system.
G.984.4 (mgt)
Eth. MAC
Cu
Phy
Codec
e.g., ETS
300 001
VLAN
PON Medium
G.984.3
G.984.2
PMD
TC
802.3
G.711Etc.
RTP/IP
IETF
TR-101
(mgt) TR-69
Sipping
Config Serv
POTS
802.3
Eth. PMD
Eth. MAC
VLAN switching
Eth. MAC
PMD
TC
IETF, TMF (mgt)
802.1
VoIP (SIP)
Figure I.14 Packet voice service
The protocol stack diagram for circuit-switched voice service is shown in Figure I.15. In this scenario,
VoIP is being used to transport the voice signals from the ONT to the class 5 TDM switch in the
central office, and no further. The protocol used in this case is usually H.248, since this system is
suited to voice gateway interfaces, of which the ONT and OLT each have one.
At the ONT, from the codec and below, the arrangement is exactly the same as in the packet voice
case.
At the OLT, the H.248 flow is terminated, usually in a special-purpose voice gateway module. This
module's function is to regenerate the customer's voice interface, and format the data representing that
interface in the way that a conventional DLC system would, as defined by the appropriate regional
standard (e.g., V5.2). This interface, most commonly carried physically by DS1 or E1 interfaces, can
then be tied directly into a class 5 switch with integrated DLC interfaces. The whole intent is to
minimize the impact of the GPON deployment on the normal operation of voice services in the CO.
The management of this kind of VoIP also has the potential for standard overlap, since all the options
are available for H.248 ONTs. However, the OMCI method is used quite often in this case, since theadvantages of the in-band system all but disappear for this scenario. The OMCI is a self-contained
solution for the management of voice services on GPON, and seems an easy choice in this scenario.
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There are additional combinations of transport protocols, functional architectures and management
protocols that are possible. The intent of the two illustrations here is to highlight the most active
combinations.
TR-101
802.1
DS-1
G.984.4 (mgt)
GR-303
VLAN
Eth. MAC Eth. MAC
Cu
Phy
Codec
e.g., ETS
300 001
VLAN
PON Medium
G.984.3
G.984.2
PMDPMD
TCTC
802.3
G.711
Etc.
RTP/IPRTP/IP
VoIP
CodecG.711
Etc.
e.g.,
V5.2
IETF
IETF, TMF (mgt)
POTS
H.248 VoIP
Figure I.15 Circuit-switched voice service
I.3.4 Circuit emulation functions
TDM interfaces can also be supported over packet transport on GPON, as shown in Figures I.16 and
I.17 (note the DS-01/E1 Framer would not be required for a transparent T1/E1 service). There are
several options that can be exercised here. The first involves the transport of the actual TDM payload,
using either a variant of the IETF PWE3 system of protocols (shown above), or the Metro Ethernet
forum's MEF 8 protocol. The second involves the use of a local OLT TDM interface (shown above)
or the use of a packet interface on the OLT leading to a gateway somewhere else in the network. This
would seem to present quite a large set of alternatives, but in practice it has turned out not to be a big
issue because most hardware supports nearly all of the options. So, interoperability is mostly a matter
of negotiating the transport protocol. Circuit emulation may also require a network clock to bedelivered to the PWE3 interworking functions. Differential timing mode supports better jitter/wander
performance than adaptive mode.
The GPON core, up to and including the VLAN layer is the same as in the typical Ethernet service.
The actual TDM interfaces are defined in, for example, [b-ITU-T G.703] for DS1 and E1 interfaces,
or the appropriate regional standard (e.g., [b-ATIS T1-107] for DS1 interfaces, [b-ETSI ETS 300 166]
for E1 interfaces).
The management of either PWE3 or MEF 8 interworking is described in [ITU-T G.984.4].
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TR-101
802.1
DS-1
Phy
G.984.4 (mgt)
DS-1framer
VLAN
Eth. MAC Eth. MAC
DS-1
Phy
e.g.,
T1-107
VLAN
PON Medium
G.984.3
G.984.2
PMDPMD
TCTC
802.3
RTP/IP
PWE3
RTP/IP
PWE3
e.g.,
T1-107
IETF, TMF (mgt)
DS-1framer
IETF
Figure I.16 Packet TDM service using PWE3 and grooming OLT
TR-101
802.1
G.984.4 (mgt)
VLAN
Eth. MAC Eth. MAC
E1
Phy
e.g., ETS
300 166
VLAN
PON Medium
G.984.3
G.984.2
PMDPMD
TCTC
802.3
MEF-8
IETF, TMF (mgt)
E1framer
MEF
802.3
Eth. PMD
Eth. MAC
Figure I.17 Packet TDM service using MEF 8 and pure OLT
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Figure I.18 shows an alternative for TDM service transport within the GPON system. This scheme
transports SDH tributary units over GEM ports directly. The definition of the format of the
encapsulated data is defined in [b-ITU-T G.707]. This scheme is mainly applicable where the TDM
service will be terminated at the OLT and transported in an SDH interface, as shown.
The management of this method at the ONT is through the OMCI ([ITU-T G.984.4]).
SDH
Phy
G.984.4 (mgt)
SDHframer
DS-1
Phy
e.g.,
T1-107
PON Medium
G.984.3
G.984.2
PMDPMD
TCTC
SDHSDH
G.957
IETF, TMF (mgt)
DS-1framer
G.707
G.707
Figure I.18 Circuit TDM service
I.3.5 Video overlay functions
Figure I.19 shows the video overlay service. This is carried on the PON using a third wavelength, andis practically distinct from the other services. The signal format delivered to the customer is defined
by SCTE standards, and the management of the ONT interface is given by [ITU-T G.984.4]. The
optical interfaces throughout the rest of the service path are generally defined by [b-ITU-T J.186]. In
practice, the details of the video OLT and subtending optical amplifiers are left to network operator
engineering, especially the signal levels at each point in the network. This is due to the large
variations in network physical topology and channel plans.
G.984.4 (mgt)
PON Medium
PMD
SCTE (mgt)
EDFA
Tx
SCTE-40
J.186
Figure I.19 Video overlay service
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Appendix II
External access network backup
(This appendix does not form an integral part of this Recommendation)
In many applications, some resilience to faults in the optical access network is desired, but the cost of
full protection as described in clause 14 is not supportable. In these cases, a cost-effective alternative
is to provide a lower capacity backup to the service via an external access network. Examples of the
external access network include digital subscriber line, fixed wireless, mobile wireless, or hybrid
fibre-coax networks.
Because of the wide range of backup access networks, the interface from the PON equipment to the
backup network has to be at the data frame networking layer, described in the IEEE 802.1 standards.
By abstracting the interface to this layer, the PON equipment need not worry about the details of the
backup network (nor does the backup network need to worry about the PON).
The key aspect of such external backup is the location and control of the backup switching logic.
Because of the widely disparate capacities of the primary PON and the backup network, it does not
make sense to send two copies of traffic at all times. Also, due to the packet-nature of the traffic, it is
difficult for the receiver to resolve multiple copies of the same packets. It is assumed that the receiver
will simply accept all packets arriving from either access network; therefore, it is important to only
send one copy of any packet. Therefore, the source side must direct the traffic to the appropriate
access network, and it must have the information required to make the correct choice. In addition, the
source side switching equipment must also have the ability to prioritize traffic and selectively discard
traffic that exceeds the capacity of the backup network when backup is in force. In the upstream, the
backup switch can be located in the ONU or beyond the UNI. In the downstream direction, thebackup switch can be located in the OLT or beyond the SNI. These arrangements are illustrated in
Figure II.1.
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Back
Up
Sw.
PON LT
AN I/F
ODNUNI LT
External
AN
Back
Up
Sw.
SNI LT
AN I/F
PON LT
ONU OLT
SNI LT
Service
Node
User
Equip.
ODN
External
AN
Back
Up
Sw.
SNI LT
AN I/F
PON LT
OLT
SNI LT
Service
Node
Back
UpSw.
PON LT
AN I/F
ODNUNI LT
External
AN
ONU
User
Equip.
PON LTODN
UNI LT
External
AN
Back
Up
Sw.
SNI LTPON LT
ONU OLT
Service
Node
User
Equip.
Back
Up
Sw.
Back
UpSw.
SNI LTPON LT
OLT
Service
Node
PON LTUNI LT
ONU
User
Equip.
Back
Up
Sw.
(a)
(b)
(c)
(d)
Figure II.1 The four switching arrangements for external access network backup
In option a), the switches are both located in the PON equipment. It is assumed that the PON
equipment has knowledge of the PON link's operational state, and therefore it can direct traffic to the
PON interface if it is working correctly and to the backup network interface if it is not. Therefore, no
additional signalling is required. The configuration of the ONU's dual ANIs must be supported in the
OMCI.
In option b), the upstream switch is located beyond the ONT's UNI. A typical situation would be for
this function to be located in an Ethernet switch or IP router. Therefore, that switch must be capable
of learning the status of the ONU's PON link via some form of signalling. This could be as crude as
the ONU deactivating the UNI when the PON link has failed, to some more sophisticated Ethernet
alarm indication signal (AIS) such as described in [b-ITU-T Y.1731]. The downstream switch is
internally controlled within the OLT.
In option c), the downstream switch is located beyond the OLT's SNI. A typical function would be for
this function to be located in an Ethernet aggregation network or service edge router. Just as in option
b), this switching logic must be given the information on the status of the PON link to the ONT in
question. Unlike the previous case, however, a sophisticated per-ONT AIS scheme must be employed
since the SNI is shared over many ONUs, some of which may not have a PON transmission problem.
This could be the AIS as described in [b-ITU-T Y.1731], but applied on a per-VLAN basis. The
upstream switch is internally controlled within the ONU, with the configuration of the ONU's dualANIs being supported in the OMCI.
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In option d), both of the switches are located beyond the PON equipment. This scheme is most
distantly removed from the access networks, since all the backup switching/routing is happening in
other equipment. This raises the possibility of allowing the backup to occur using the more
autonomous schemes such as Ethernet spanning tree or IP routing. In either case, the backup link
would need to be configured as the 'expensive link', so that it would not be used if the PON link was
available. These Layer 2 or 3 schemes tend to take longer than more direct schemes mentioned in the
previous options a-c. Their performance could be improved by implementing the direct AIS schemesto provide a faster feedback into their control algorithms.
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Appendix III
Dual-parenting resilience
(This appendix does not form an integral part of this Recommendation)
Dual-parenting resilience refers to a system where PON protection is implemented using two OLT
line terminations that are provided in two separate OLT equipment, typically in physically diverse
locations. Such a scheme offers protection from catastrophic failure of the OLT equipment, its power
supply, and the physical locality where it is placed.
Unlike traditional PON protection, where both PON sections terminated in the same equipment, dual
parenting requires coordination of the functions of two PONs in separate equipment. The prerequisite
to accomplish this is that the ONUs being protected must be registered on both the working and
remote OLTs. In this way, the logical state of the working OLT can be reproduced in the protection
OLT with a minimum of delay. In addition, the protection switching of traffic upstream from both
OLTs must also be supported. This topic is for future study, and is out of the scope of this discussion.
In dual-parenting type B protection, shown in Figure III.1, the main functionality to implement
resilience resides within the OLT. This scheme requires the protection OLT to be in standby state,
therefore it is necessary to synchronize the operation status of both OLTs. Additionally, a data
communications channel is necessary between the two OLTs for sharing the service configuration of
all ONUs that is needed to re-establish the connections between all UNIs and SNIs at the remote OLT
(Figure III.1).
PON LT (1)
OLT
ONU #1
PON LT (0)
OLT
Inter OLT
communications
channel
ODN
ONU #N
PON LT (1)PON LT (1)
OLT
ONU #1
PON LT (0)PON LT (0)
OLT
Inter OLT
communications
channel
ODNODN
ONU #N
Figure III.1 Diagram showing a communications channel between
working and remote standby OLTs
The data communications channel between the two OLTs can be implemented in different ways. One
straightforward method is using the management plane at either the element management layer or
network management layer (Figure III.2).
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PON LT (1)
OLT
PON LT (0)
OLTTMN
Q3
Q3
ODN
ONU #1
ONU #N
PON LT (1)PON LT (1)
OLT
PON LT (0)PON LT (0)
OLTTMN
Q3
Q3
ODNODN
ONU #1
ONU #N
Figure III.2 Inter-OLT communications channel established through management plane
The events that trigger dual-parenting switching are:
1) Fibre cut in the ODN on the working OLT side.
2) Degraded link.
3) Failure of the PON LT in the OLT.
4) OLT failure.
The standby remote OLT could be triggered (enabled) after asserting PON LT LOS and a second
check via inter-OLT communications channel. A dying gasp message from all ONUs should prevent
dual-parenting switch-over.
The remote standby OLT should maintain, as a minimum, the serial number list of registered ONUs
and the service profile of each ONU. Optionally, other data are also possible to be shared between
working and remote OLT in order to speed up service recovery.
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line transceivers 2 (VDSL2).
[b-ITU-T G.8261] Recommendation ITU-T G.8261/Y.1361 (2006), Timing and synchronization
aspects in packet networks.
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http://webstore.ansi.org/RecordDetail.aspx?sku=ANSI+T1.102-1993+(R2005)http://webstore.ansi.org/RecordDetail.aspx?sku=T1.107-2002+(R2006)http://webstore.ansi.org/RecordDetail.aspx?sku=T1.105.06-2002(R2007)http://webstore.ansi.org/RecordDetail.aspx?sku=T1-DIHI-101http://www.broadband-forum.org/technical/download/TR-101.pdfhttp://pda.etsi.org/pda/home.asp?wki_id=I0hgmKBC_Ervutu_Uf,Uhttp://pda.etsi.org/pda/home.asp?wki_id=FFfpCKzkIhlnuqJbxVGhttp://ieeexplore.ieee.org/servlet/opac?punumber=9155http://ieeexplore.ieee.org/servlet/opac?punumber=10531http://ieeexplore.ieee.org/servlet/opac?punumber=4248376http://metroethernetforum.org/PDFs/Standards/MEF8.pdfhttp://webstore.ansi.org/RecordDetail.aspx?sku=ANSI+T1.102-1993+(R2005)http://webstore.ansi.org/RecordDetail.aspx?sku=T1.107-2002+(R2006)http://webstore.ansi.org/RecordDetail.aspx?sku=T1.105.06-2002(R2007)http://webstore.ansi.org/RecordDetail.aspx?sku=T1-DIHI-101http://www.broadband-forum.org/technical/download/TR-101.pdfhttp://pda.etsi.org/pda/home.asp?wki_id=I0hgmKBC_Ervutu_Uf,Uhttp://pda.etsi.org/pda/home.asp?wki_id=FFfpCKzkIhlnuqJbxVGhttp://ieeexplore.ieee.org/servlet/opac?punumber=9155http://ieeexplore.ieee.org/servlet/opac?punumber=10531http://ieeexplore.ieee.org/servlet/opac?punumber=4248376http://metroethernetforum.org/PDFs/Standards/MEF8.pdf -
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SERIES OF ITU-T RECOMMENDATIONS
Series A Organization of the work of ITU-T
Series D General tariff principles
Series E Overall network operation, telephone service, service operation and human factors
Series F Non-telephone telecommunication services
Series G Transmission systems and media, digital systems and networks
Series H Audiovisual and multimedia systems
Series I Integrated services digital network
Series J Cable networks and transmission of television, sound programme and other multimedia
signals
Series K Protection against interference
Series L Construction, installation and protection of cables and other elements of outside plant
Series M Telecommunication management, including TMN and network maintenance
Series N Maintenance: international sound programme and television transmission circuits
Series O Specifications of measuring equipment
Series P Telephone transmission quality, telephone installations, local line networks
Series Q Switching and signalling
Series R Telegraph transmission
Series S Telegraph services terminal equipment
Series T Terminals for telematic services
Series U Telegraph switching
Series V Data communication over the telephone network
Series X Data networks, open system communications and security
Series Y Global information infrastructure, Internet protocol aspects and next-generationnetworks
Series Z Languages and general software aspects for telecommunication systems